JPH08505039A - Power supply system for plug-in modules - Google Patents

Abstract

(57) [Summary] A system for supplying primary power to modular components of electronic equipment. The system uses a battery power source (410) installed as a module (200) or as part of a battery pack installed in the module (200). The module circuit (400) supplies the recharge current to the battery power source (410). The charging circuit charges the battery (410) in parallel, and connects the battery (410) to the module (200) in series to supply electric power. The circuit (400) also determines the amount of battery power (410) used to operate the module (200) and provides a recharge current to the battery power (410) as a function of power consumed by the module (200). Send based on available recharge current.

Description

DETAILED DESCRIPTION OF THE INVENTION CROSS REFERENCE TO SPECIFICATIONS FOR POWER SUPPLY SYSTEMS FOR PLUGIN MODULES This specification is pending US Patent Serial No. 08 / 026,478, filed March 4, 1993, entitled "Modular Wireless communication system ", inventor Per Stein; which is assigned to the same assignee as the present invention; and is also referenced herein in its entirety. BACKGROUND OF THE INVENTION Industrial applications The present invention relates to modular electronics, and more particularly to modular wearable electronic components and / or devices that require supplemental power. History of conventional technology Electronic equipment systems have undergone significant technological advances in recent years. One of these advances is The use of modular electronics components or devices within an electronics system. Like a plugin module, Modular electronics components allow replacement of circuit components of the electronics system without having to disassemble or reassemble the electronics system itself. Modular electronics equipment also It is also possible to expand the capacity and functions of the basic electronic device system. The electronics system is designed to accept standard format plug-in modules. The plug-in module that conforms to the standard format is Different functional designs are possible for use with electronics systems. A plugin module with this standard format in this way Can be replaced when the user wishes to change to the additional functionality provided by those plugin modules. As an example, Recently, there is a movement to standardize the internal connection format used in circuit boards for personal computers. In particular, PC & Memory Card International Association (PCMCIA) It was founded to promote the compatibility of integrated circuits and memory cards between computers and other types of electronic products. To this end, PCMCIA promulgates several physical and electrical standards, We are trying to ensure that these cards can be used in different devices. Built according to these standards, Data storage, Ie memory and peripheral expansion, That is, any I / O card type It must be possible to use any connector built to this standard. Therefore, the computer system using the PCMCIA format can exchange modules, This extends the functions that can be performed on the host computer system. Another advance in electronics systems is the miniaturization of computer systems as well as electronics components. For example, a personal computer Its desktop, Laptop, As we progress through the notebook and palmtop editions, they are becoming smaller and more efficient. However, This progress in miniaturization faces certain restrictions on the plug-in modules used in these systems. A plug-in module usually requires power from its host device. As electronic devices are getting smaller, Limited power is available from electronic devices for use in plug-in modules. This limitation is becoming more prominent as personal computers become laptop or palmtop versions. The portability requirements of these systems are fixed power supplies, For example it prevents using unlimited power from a wall socket. The miniaturization of the host system is We are facing battery size constraints for powering host systems as well as plug-in modules. As a result of these two restrictions, There is a hard limit on the power available to plug-in modules. However many plugin modules, For example, disk drives or wireless transceivers have high voltage, Large peak current capacity, Requires a larger total power capacity or a combination of these, Many host systems exceed the range of power that can be supplied to the plug-in module within these limits. Some plug-in modules have a built-in backup battery for use when the power supply from the host device is lost. The module containing the backup battery is typically a memory module, which constantly requires a small amount of maintenance power. The purpose of the backup battery is to supply a very small amount of maintenance power to the plug-in module when the power from the host device is lost. However, plug-in modules that require a larger power source during operation cannot be backed up by a battery. Therefore, If the power supplied from the host device is insufficient for the operation of the module, It would be beneficial to provide a plug-in module with a power supply that can support the operation of the plug-in module. The system according to the invention and its various components provide such features. SUMMARY OF THE INVENTION The present invention relates generally to modular electronics. More specifically, The present invention provides a system for providing primary power to modular wearable electronics components or devices mounted in host electronics. As one mode of the present invention, Modular electronics components have built-in battery power, This is to power the operation and functions of this modular electronics, Provides power to modular electronics components. In another aspect of the invention, A battery pack having a battery power source is removably attached to the modular electronics component to provide primary power to the modular electronics component. In yet another aspect of the invention, The host electronics supply power to the modular electronics components, The battery power source supplements the power from the host electronics. In yet another embodiment of this aspect of the invention, The battery power supply provides power to the modular electronic component only when the power from the host electronic device is insufficient to operate the modular electronic component. In yet another aspect of the invention, The battery power supply device is a plurality of batteries electrically connected in a series configuration. In yet another aspect of the invention, Modular electronics components include a wireless transmitter and a battery powered device provides power to operate the transmitter. In yet another aspect of the invention, The transmitter has a higher power consumption rating when used on battery power, It also has a lower power consumption rating when used without battery power, The modular electronics component has a device for switching the transmitter between two consumption levels. In yet another aspect of the invention, The device for switching the transmitter power consumption level is from a high power consumption level to a low power consumption level, In addition, it is possible to automatically switch in the opposite direction according to the ability of the battery power source to supply the required power. In yet another aspect of the invention, This switching device detects when the battery pack is attached to a modular electronic component, Switch the transmitter to a high power consumption level when the battery pack is installed, If the battery pack is not installed, switch to a low power consumption level. In yet another aspect of the invention, A charging circuit supplies current to the battery power supply for recharging. In yet another aspect of the invention, The charging circuit resides in the host electronics. In yet another aspect of the invention, The charging circuit resides in the modular electronics component. In yet another aspect of the invention, This charging circuit is present in the battery pack. In another aspect of the invention, The modular electronics component contains a battery power supply which supplies power to the modular electronics component and Have sufficient power capacity to power a limited number of high current demand operations of modular electronics components, Modular electronics components represent the number of high current demands a battery power supply can fulfill, It can be expanded by recharging the battery power supply device with the recharging current supplied from the host electronic device. In yet another aspect of the invention, The modular electronics component is the PCMC IA module, The battery power supply is recharged from a 12 volt power supply provided by the host electronics such as a PCMCIA type module. In yet another aspect of the invention, The battery power supply is recharged from the 5 volt power supply when the 12 volt power supply is unavailable, And the battery power supplies are connected in series when the power demand is high, It has two batteries connected in parallel for recharging when power requirements are low. In another aspect of the invention, Modular electronic components include a battery power supply and a control circuit, It calculates the amount of charge used in modular electronics components, When the power demand is low, a corresponding charge is sent to the battery power source. In yet another aspect of the invention, The modular electronics device is a PCMCIA type module with a burst mode radio transmitter. In another aspect of the invention, The modular electronics component is a PCMCIA type module with a battery power supply for supplying power to the PCMCIA type module. In yet another aspect of the invention, The battery power supply is part of a battery pack that is removably mounted in a PCMCIA type module. In yet another aspect of the invention, This PCMCIA type module incorporates a wireless transmitter. In yet another aspect of the invention, PCMCIA type modules have a high power consumption rating used with a battery power source, With a low power consumption rating used without battery power, The modular electronics component then comprises a device for switching the transmitter between two consumption levels. In yet another aspect of the invention, The device for switching the transmitter power consumption level is from a high power consumption level to a low power consumption level, In addition, it is possible to automatically switch in the opposite direction according to the ability of the battery power source to supply the required power. In yet another aspect of the invention, This switching device detects when the battery pack is attached to a modular electronic component, Switch the transmitter to a high power consumption level when the battery pack is installed, If the battery pack is not installed, switch to a low power consumption level. In yet another aspect of the invention, A charging circuit supplies current to the battery power supply for recharging. In yet another aspect of the invention, The charging circuit resides in the host electronics. In yet another aspect of the invention, The charging circuit resides in the PCMCIA type module. In yet another aspect of the invention, This charging circuit is present in the battery pack. In yet another aspect of the invention, One antenna is pivotally attached to the battery pack, It is electrically connected to a wireless transmitter in a PCMCIA type module. BRIEF DESCRIPTION OF THE DRAWINGS For a more complete understanding of the present invention and further objects and features thereof, See the description below in combination with the attached figures, here: Figure 1 shows FIG. 3 is an exploded perspective view of a modular device constructed in accordance with the present invention, Illustrates its multiple applications; Figure 2 shows A block diagram illustrating a modular circuit constructed in accordance with the principles of the present invention; Figure 3 shows Built on the principles of the invention, Circuit diagram of an embodiment of the charging circuit and battery power supply shown in FIG. 2; Figure 4 shows Built on the principles of the invention, Circuit diagram of another embodiment of the charging circuit and battery power source shown in FIG. 2; Figure 5 shows 2 illustrates an application example of a laptop computer using a modular memory device constructed in accordance with the principles of the present invention, Exploded perspective view; Figure 6A shows 6 is a top plan view of the modular memory device of FIG. 5, 3 illustrates various aspects of embodiments of the present invention; Figures 6B-D An elevational view of the modular memory device of FIG. 6A, respectively. Rear elevation, And a side elevation sectional view, Further illustrated are various forms of embodiments of the present invention; Figure 7 shows 2 illustrates an application example of a laptop computer using a modular telecommunications device constructed in accordance with the principles of the present invention, Exploded perspective view; Figure 8A shows 8 is a top plan view of the modular telecommunication device of FIG. 7. 3 illustrates various aspects of embodiments of the present invention; Figures 8B-D FIG. 8A is an elevational view of the modular telecommunication device of FIG. 8A, respectively. Rear elevation, And a side elevation sectional view, Further illustrated are various forms of embodiments of the present invention; Figure 9 shows Built on the principles of the invention, With battery pack termination, Illustrates an application example of a laptop computer using a modular memory device, Exploded perspective view; Figure 10A shows FIG. 10 is a top plan view of the modular memory device of FIG. 9 with the battery pack removed, 3 illustrates various aspects of embodiments of the present invention; Figures 10B-D Elevated view of the modular memory device of FIG. 8A, each with the battery pack removed, Rear elevation, And a side elevation sectional view, Further illustrated are various forms of embodiments of the present invention; Figure 11 shows FIG. 10 is an exploded perspective view of a battery pack of the modular memory device of FIG. 9, 3 illustrates various aspects of embodiments of the present invention; Figure 12 shows Built on the principles of the invention, Have a battery pack, Illustrates an application of a laptop computer using a modular telecommunication device, Exploded perspective view; Figure 13A shows FIG. 13 is a top plan view of the modular telecommunications device of FIG. 12 with the battery pack removed, 3 illustrates various aspects of embodiments of the present invention; 13B-D, Elevated view of the modular telecommunication device of Figure 13A, each with the battery pack removed, Rear elevation, And a side elevation sectional view, Further illustrated are various forms of embodiments of the present invention; And in Fig. 14, 13 is an exploded perspective view of the battery pack of the modular telecommunication device of FIG. 12, 6 further illustrates various aspects of embodiments of the present invention. Detailed Description of Embodiments Referring first to FIG. Built here based on the principles of the invention, The diverse and versatile uses made possible by the plug-in module 200 are illustrated. The plug-in module 200 has a built-in module circuit and a battery power source, Both of them will be described in detail below. The module circuit regulates the power distribution from the battery power source to the plug-in module 200. The module circuit is also capable of supplying recharge current to the battery power source. Battery power can also be built into the plug-in module, Alternatively, it may be a part of the battery pack mounted on the plug-in module 200. The battery power supply uses the primary power for the module operation of the plug-in module 200, Provide the required power supply more than the host system can supply. The plug-in module 200 can be designed to perform various functions for the host system. Examples of functions that the plug-in module 200 can execute are Although not limited to this, Memory expansion, Telecommunications modem, Alternatively, it includes a wireless communication module. The plug-in module 200 can be designed to be compatible with various types of host equipment. As shown in FIG. 1, the module 200 includes a laptop computer 102, Cellular telephone 104, Alternatively, it can be used as the pen input computer 106. Host devices that can use these types of modules 200 are: I just gave an example, These are not exhaustive and not limiting of the invention. Although the host device illustrated in the examples described below is a laptop computer, The present invention is not limited to use with a computer, Any type of electronic device can be used as the host device. Referring to FIG. 2, Shown here is a block diagram of an exemplary module circuit 400 constructed in accordance with the principles of the present invention. The module circuit 400 is generally a battery power source 410, Charging circuit 420, Load 430, And a microprocessor 440. The microprocessor 440 sends the transmission signal via the transmission control line 490, The load 430 is instructed to operate for a specified time. In order to operate the load 430 through the power supply line 480, In addition, power is consumed from the battery power supply device 410 at a known rate. Since the power consumption rating of the load 430 is a known constant, The microprocessor 440 can determine how much power the load 430 consumes from the battery power supply 410 during a particular operating period. Continuing to refer to FIG. After the load 430 completes the operating period, The microprocessor 440 is It issues a command to send the recharge current to the battery power supply device 410 via the charge control line 470. The recharge current from the charging circuit 420 is sent to the battery power source 430 at a known constant rate. The microprocessor 440 is The recharge current is commanded to be sent to the battery power source 410 based on the power consumed by the load 430 during the operation period. Normally, the charging circuit 420 supplies the recharging current to the battery power source 410. The load 420 is sent at a rating lower than the rating consumed during operation. The microprocessor 440 therefore calculates the difference between this consumption rating and the recharge rating as The solution is to instruct the charging circuit 420 to charge the battery 410 for a longer time. The recharging period is set by the microprocessor 440. Load 430 consumption rating, The length of the driving period, And the recharge rate. The microprocessor 440 uses these three parameters to determine the recharge period, This recharges the battery power source 410 to its original state. 2 illustrates the use of the microprocessor 440, Any similar type of control circuit can be used to control the load 430 as well as the charging circuit 420. Also referring to FIG. 2, Load 430 can be any electrical consumer device located within module 200 of FIG. For example, The load 430 is a disk drive device, Wireless transmitter, Or any other high power consumption device is possible. Although modular circuit 400 is shown receiving 5 volt and 12 volt power from the host equipment, Any single or combined voltage can be used for the modular circuit 400. The battery power source 410 is a single battery or a plurality of batteries, It does not matter if they are connected in a series or parallel configuration. The charging circuit 420 and the microprocessor 440 need not be located in the module, In fact it can be placed anywhere. The modular circuit 400 shown in FIG. 2 is shown for illustration purposes only, It is not absolutely necessary or limiting to the invention. For example, you can connect the battery power supply device directly to the power supply line that is supplied from the host device to the Or you can supply electricity independently to the components in the module, Other similar methods are also possible. Next, referring to FIG. Here, a circuit diagram of one embodiment of the charging circuit 420 and the battery power source 410 of FIG. 2 is shown. As can be seen, the charging circuit 420 of FIG. 3 implements automatic switching between the 5 volt power supply 460 and the battery 610 of the battery power supply 410. If the voltage of battery 610 is higher than 5 volt power supply 460, Battery 610 supplies power to power supply line 480 through diode 540b. Due to breakdown or other reasons If the voltage of the battery 610 is lower than the 5 volt power supply 460, The charging circuit 420 supplies electric power to the power supply line 480, Supply from a 5 volt power supply 460 through diode 540a. Continuing to refer to FIG. If the charging control line 470 does not send a charging signal to the charging circuit 420, The transistor 530 does not become conductive, and the transistor 520 A low charging current is supplied to the battery 610 as defined by the emitter resistor 510a and the base bias resistors 510b-c. When the charge control line 470 sends a recharge signal to the transistor 530, Transistor 530 becomes conductive and changes the bias voltage of transistor 520 (by grounding through resistor 510d), Let the higher charging current be the value provided to battery 610 through transistor 520. Next, referring to FIG. A circuit diagram of another embodiment of the charging circuit 420 and the battery power source 410 of FIG. 1 is shown here. In the embodiment illustrated in FIG. 4, charging circuit 420 requires only a 5 volt power supply 460 from the host electronics. In the embodiment shown in FIG. The charging circuit 420 and the battery power source 410 are When more power is required for the power supply line 480, Connecting the battery 610a and the battery 610b in a series configuration, It also provides the ability to connect batteries 610a-b in a parallel configuration for charging when power is not needed. When the charge control line does not receive the recharge signal, It can be seen that transistor 570 is non-conductive and batteries 610a-b are charged from 5 volt power supply 460 through resistors 560a-b. When a recharge signal is sent through charge control line 470, Transistor 570 becomes conductive and power supply line 480 is powered by two batteries 620a-b connected in series. In the circuit diagram shown in FIG. 4, The diode 580 is used when the voltage of the batteries 620a-b is extremely low, And when the recharge signal is sent on the charge control line 470, the power supply line 480 is powered from the 5 volt power supply 460. The plurality of resistors 560a-d can be selected to provide a particular voltage to various components of modular circuit 400. Next, referring to FIG. Built here based on the principles of the invention, A modular memory device used in laptop computer 110, Alternatively, component 210 is shown. A modular circuit similar to the circuit shown in FIGS. It can be located in either the laptop computer 110 or the modular memory device 210. The laptop computer 110 has a computer module compartment 111 and a computer module connector 113. The modular memory device 210 has a modular body 211 and a module connector 213. The module body 211 of the modular memory device 210 is It is designed to fit within the computer module compartment 111 of the laptop computer 110. The module connector 213 is provided when the modular memory device 210 is inserted into the computer module compartment 111. It is designed to connect with the computer module connector 213. Computer module section 111, Module connector 113, Module body 211 And the design of the module connector 213 is It can be a standardized design, such as the PCM CIA standard for memory cards. In this way The module can be standardized for use as a multi-modal model of host equipment. Next, referring to FIG. 6A-D in combination, The modular memory device 210 of FIG. 5 is illustrated here. The module connector 213 is arranged at the tip of the module body 211. The module main body 211 has a built-in printed circuit board 214, It is connected to the module connector 213. A rear plate 212 is arranged at the rear end of the module body 211 and surrounds the printed circuit board 214 in the module body 211. A battery 215 is mounted on the printed circuit board 214 in the module body 211. Although FIGS. 6A-D show only one battery as a power source, It is also possible to connect and use a plurality of batteries in a parallel or series configuration. In one embodiment, Battery 215 is designed to provide all of the power needed to operate modular memory device 210. In another embodiment, Battery 215 is designed to supplement the power from laptop computer 110 for use in operating memory module 210. In yet another embodiment, Battery 215 is designed to provide power only when the power provided by the host computer is insufficient to operate the functions of modular memory device 210. Battery 215 can be implemented with a NiCad type battery or similar rechargeable battery. The module body 211 can be made of metal or plastic. Next, referring to FIG. For use in a laptop computer 120, A modular telecommunications device constructed according to the principles of the present invention, Or component 220 is shown. The embodiment illustrated in FIG. 7 also Related pendant specification 08/026, previously incorporated as reference It is also built on the principles taught by 478. A modular circuit similar to the circuit shown in FIG. It can be located in either the laptop computer 120 or the modular memory device 220. The laptop computer 120 has a computer module compartment 121 having a module connector 123, Antenna 124, Also includes a computer antenna connector 126. The module telecommunication device 220 A modular body 221, designed to fit within the computer module compartment 121, A module connector 223 designed to interface with the computer module connector 123, And a module antenna connector 226 designed to interface with the computer antenna connector 126. Next, referring to FIGS. 8A-D in combination, A modular telecommunication device 220 from FIG. 7 is shown here. The module connector 223 is arranged at the tip of the module body 221. The module body 221 has a printed circuit board 224 built-in, It interfaces with the module connector 223. A module antenna connector 226 is mounted in the area behind the printed circuit board 224. A back plate 222 surrounds the printed circuit board 224 within the module telecommunications device 220, It has one opening that allows access to the module antenna connector 226. A battery 225 is mounted on the printed circuit board 224 to power the modular telecommunication device 220. Although FIGS. 8A-D show only one battery as a power source, It is also possible to connect and use a plurality of batteries in a parallel or series configuration. In one embodiment, Battery 225 is designed to provide all of the power needed to operate modular telecommunication device 220. In another embodiment, Battery 225 is designed to supplement the power from laptop computer 120 for use in operating modular telecommunication device 220. In yet another embodiment, Battery 225 is designed to provide power only when the power provided by laptop computer 120 is insufficient to operate the functionality of modular telecommunications device 220. Battery 225 can be implemented with a NiCad type battery or similar rechargeable battery. The module body 221 can be made of metal or plastic. Next, referring to FIG. For use in a laptop computer 130, A modular memory device 230 is shown constructed in accordance with the principles of the present invention. The laptop computer 130 has a computer module compartment 131 and a computer module connector 133. The modular memory device 230 is composed of a modular memory component 260 and a battery pack 270. The modular memory component 260 is a module body 261 designed to fit within the computer module compartment 131. And a module connector 263 for interfacing with the computer module connector 133. Battery pack 270 is designed to interface with the rear region of modular memory component 260. The battery pack 270 is illustrated as popping out of the computer module compartment 131 when the modular memory device 230 is plugged into the laptop computer 130. The battery pack 270 can also be designed to be housed inside the computer module compartment 131. A modular circuit similar to the circuit shown in FIG. Laptop computer 130, It can be located in either the modular memory component 260 or the battery pack 270. Referring now to FIGS. 10A-C, Illustrated here are the modular memory components 260 of the modular memory device 230 shown in FIG. The module main body 261 incorporates electronic device components necessary for executing the functions of the modular memory device 230. The module connector 263 is arranged in the front part of the module body. In the rear area of the module body 261, there is a back plate, This allows access to the power connector plug 267 within the modular memory component 260. A fastener 269 for engaging with the battery pack fastener 279 is also arranged in the rear plate 262. Computer module compartment 131, Computer module connector 133, Module body 231, And the design of the module connector 233 is For example, it can be a standardized design such as the PCMCIA standard for memory cards. In this way the module can be standardized for use with multiple types of host equipment. Next, referring to FIG. Here, an exploded perspective view of the battery pack 270 from the modular memory device 230 of FIG. 9 is shown. The battery pack 270 has a front portion 271, And a rear portion 272 containing a battery source 275. The battery source 275 may include a plurality of batteries connected in series or in parallel with each other. Alternatively, a single battery may be used. The batteries used in battery source 275 are NiCad type batteries or similar rechargeable batteries. The battery source 275 is connected to the power connector plug 277 by power lines 278a-b. The power connector plug 277 extends outside the front portion 271 of the battery pack 270, It is adapted to mate with a power connector plug 267 located in the modular memory component 260 of FIG. The battery pack fastener 279 is arranged so as to extend through the front portion 271 of the battery pack 270, It is adapted to mate with a fastener insert 269 located on the modular memory component 260 of FIG. Next, the ninth 10A-D, And referring to FIG. 11 in combination, It can be appreciated how the battery pack 270 as well as the modular memory components 260 are combined and interfaced with the laptop computer 130. The front portion 271 of the battery pack 270 is adapted to mate with the module body 261 of the modular memory component 260. The power connector plug 277 of the battery pack 270 interfaces with the power connector plug 267 of the modular memory component 260. The battery pack fastener 279 meshes with the fastener insertion 269, This secures the battery pack 270 to the modular memory component 260. Finally, the modular memory component 260 is placed in the computer module compartment 231 and Module connector 263 interfaces with computer module connector 133. In this way The modular memory device 230 provides the required functionality to the laptop computer 130, The battery pack 270 can supply power to the modular memory device 230. Then the ninth, 10A-D, And referring to FIG. 11 in combination, In one embodiment, Battery pack 270 is designed to provide all of the power needed to operate modular memory device 230. In another embodiment, Battery pack 270 is designed to supplement the power from laptop computer 130 for use in operating modular memory device 230. In yet another embodiment, The battery pack 270 is designed to power the modular memory device 230 only when the power supplied from the laptop computer 130 is insufficient to operate the functions of the modular memory device 230. It is possible to place the switching device in the power connector plug 267 or on the modular memory component 260, This detects the presence of the battery pack 270, When the battery pack 270 is not attached to the modular memory component 260, Switching modular memory components 260 to low power consumption ratings, When the battery pack 270 is installed in the modular memory component 260, it switches to a high power level consumption rating. Next, referring to FIG. For use in the laptop computer 140, A modular telecommunications device 240 is shown constructed in accordance with the principles of the present invention. The embodiment illustrated in FIG. 12 also Related pendant specification 08/026, previously incorporated as reference It is also built on the principles taught by 478. The laptop computer 140 has a computer module compartment 141 and a computer module connector 143. The modular telecommunications device 240 comprises modular telecommunications components 280 and a battery pack 290. The modular circuit component 280 has a module body 281 designed to fit within the computer module compartment 141. The modular telecommunications component 280 also It also has a module connector 283 that interfaces with the computer module connector 143 of the laptop computer 140. Battery pack 290 is designed to interface with the rear end of modular telecommunications component 280. Although the modular telecommunication device 240 is shown as having a battery pack 290 that pops out of the computer module compartment 141, The modular telecommunication device can also be designed such that the battery pack 290 is housed inside the computer module compartment 141. A modular circuit similar to the circuit shown in FIG. Laptop computer 140, It can be located in either the modular telecommunications component 280 or the battery pack 280. Referring now to FIGS. 13A-C, Illustrated herein are the modular telecommunications components 280 of the modular telecommunications device 240 shown in FIG. Module body 281 contains the circuitry necessary to perform the functions of modular telecommunications device 240. The module connector 283 is arranged in the front part of the module body 281. At the rear end of the module body 281, there is a rear plate 282, This allows access to the antenna connector plug 287 and the power connector plug 287 in the modular telecommunications component 280. Back plate 282 also includes fastener inserts 289 for securing battery pack 290 to modular telecommunications component 280. Next, referring to FIG. Here, an exploded perspective view of the battery pack 290 from the modular telecommunication device 240 of FIG. 12 is shown. The battery pack 290 has a front part 291 and And a rear portion 292 that houses a battery source 295. The battery source 295 may include a plurality of batteries connected in a series or parallel relationship with each other. Alternatively, a single battery may be used. The batteries used in battery source 295 are NiCad type batteries or similar rechargeable batteries. The battery source 295 is connected to the power connector plug 297 by power lines 298a-b. The power connector plug 297 extends outside the front part 291 of the battery pack 290, It is adapted to mate with a power connector plug 287 located in the modular telecommunications component 280 of FIGS. 13A-C. Continuing to refer to FIG. 14, In order for the antenna connector plug assembly 296 to mate with the antenna connector plug 287 of the modular telecommunications component 280 of Figures 13A-C, It is mounted in the front part 291 of the battery pack 290. The antenna 294 is pivotally mounted in the front part 291 of the battery pack 290, To provide electrical continuity between the antenna 294 and the antenna connector plug 296, The opening in the antenna connector plug assembly 296 is in contact. The battery pack fastener 299 is arranged so as to penetrate through the front portion 291 of the battery pack 290, It is adapted to mate with a fastener insert 289 located on the modular telecommunications component 280 of FIG. Next, twelfth 13A-D, And referring to FIG. 14 in combination, It can be appreciated how the battery pack 290 as well as the modular telecommunications component 280 are combined and interfaced with the laptop computer 140. The front portion 291 of the battery pack 290 is adapted to mate with the module body 281 of the modular telecommunications component 280. The power connector plug 297 of the battery pack 290 interfaces with the power connector plug 287 of the modular telecommunications component 280. Antenna connector plug assembly 296 of 290 interfaces with antenna connector plug 286 of modular telecommunications component 280. The battery pack fastener 299 meshes with the fastener insertion 289, This secures the battery pack 290 onto the modular telecommunications component 280. Finally, the modular telecommunications component 280 is placed in the computer module compartment 241 and Module connector 283 interfaces with computer module connector 143. In this way The modular telecommunication device 240 provides the required functionality to the laptop computer 140, Battery pack 290 can provide power to modular telecommunications component 280 and continuity to antenna 294. 12th, 13A-D, And referring to FIG. 14 in combination, In one embodiment, Battery pack 290 is designed to provide all of the power needed to operate modular telecommunication device 240. In another embodiment, Battery pack 290 is designed to supplement the power from laptop computer 140 for use in operating modular telecommunications device 240. In yet another embodiment, The battery pack 290 is designed to power the modular telecommunications device 240 only when the power provided by the laptop computer 140 is insufficient to operate the functions of the modular telecommunications device 240. One example of when the power supplied from the laptop computer 140 is insufficient is When the modular telecommunication device 240 is operating in burst transmission mode. It is possible to place the switching device in the power connector plug 287 or on the modular telecommunications component 280, This detects the presence of the battery pack 290, When the battery pack 290 is not attached to the modular telecommunications component 280, Switching modular telecommunications components 280 to low power consumption ratings, Switches to a high power level consumption rating when the battery pack 290 is attached to the modular telecommunications component 280. Therefore, it is believed that the operation and configuration of the present invention have been clarified from the above description. Although the method and apparatus shown or described have been characterized as submitted, It will be apparent that various changes and modifications can be made without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (1)

[Claims]   1. Primary to modular electronics components for use in host electronics A system for supplying power:   A battery power source disposed within the modular electronics component;   A device for electrically coupling the battery power source to the modular electronic component. And; and   The modular electronics component for operation of the modular electronics component And a battery power supply for supplying primary power to the system.   2. The system of claim 1, wherein the host electronic device is the module. Is adapted to provide primary power to the electronic components and Power that power is supplied from the host electronics to the modular electronics components The system is adapted to supplement.   3. The system according to claim 2, wherein power is supplied from the host electronic device. When battery power is insufficient to operate the modular electronics components, the battery power The modular electronics component being adapted to power the Stem.   4. The system according to claim 1, wherein the battery power sources are connected in series. The system consisting of a number of batteries.   5. The system of claim 1, wherein the modular electronic component Includes a wireless transmitter, and the battery power source provides power to operate the transmitter. The system is adapted to:   6. In the system according to claim 5,   High power consumption level when the transmitter uses the battery power as a power supply In order to maintain a low power consumption level when the battery power supply is not used, Built; and   In connection with the modular electronic components, the transmitter is connected to the high power consumption level. And a device for switching between the low power consumption level and the low power consumption level. .   7. 7. The system according to claim 6, wherein the transmitter is turned off at a power consumption level. When the device for replacement can supply the power required by the battery power source, Automatically switch to the high power consumption level and the battery power source If it cannot supply the required power, it will automatically switch to the low power consumption level. The system including a device for replacement.   8. The system according to claim 1, wherein the charging circuit is connected to the battery power source. And a charging circuit adapted to provide a recharging current to the battery power source. The system as described above.   9. 9. The system according to claim 8, wherein the charging circuit is the host electronic device. The system is disposed in a container.   10. The system of claim 8, wherein the charging circuit is the modular The system as located within an electronic component.   11. It is a modular electronic component for use in host electronics. A system for supplying the following power:   A rechargeable battery mounted inside the modular electronic component A battery pack having a source;   From the battery power supply in the battery pack to the modular electronic component And a device for directing electric power; and   The modular electronics component for operation of the modular electronics component A battery power supply adapted to provide primary power to the system.   12. The system of claim 11, wherein the host electronic device is the module. Is adapted to provide primary power to the Jura electronics component, and Pond power is supplied from the host electronics to the modular electronics components The system, which is adapted as a power source to supplement power.   13. 13. The system according to claim 12, wherein power from the host electronic device is used. When the power supply is insufficient to operate the modular electronic components, the battery power Is adapted to power the modular electronics components, Writing system.   14. The system according to claim 11, wherein the battery power source is connected in series. The system, which is composed of a plurality of batteries.   15. The system of claim 11, wherein the modular electronic equipment configuration. The component includes a wireless transmitter, and the battery power supply provides power to operate the transmitter. The system adapted to dispense.   16. In the system according to claim 15,   High power consumption level when the transmitter uses the battery power as a power supply In order to maintain a low power consumption level when the battery power supply is not used, Built; and   In connection with the modular electronic components, the transmitter is connected to the high power consumption level. And a device for switching between the low power consumption level and the low power consumption level. .   17． The system according to claim 16, wherein the transmitter has a power consumption level. When the device for switching the battery can supply the power required by the battery power source. Automatically switch to the high power consumption level, the battery power When the power required by the level cannot be supplied, the low power consumption level is automatically set. The system including a device for switching.   18. In the system of claim 16, wherein:   The switching device attaches the battery pack to the modular electronic component. Adapted to detect whether it is worn; and   The switching device is also the battery pack and the modular electronic device components. To operate the transmitter at the high power consumption level when attached to Switch, the battery pack is not attached to the modular electronic component. The system being adapted to switch to the low power consumption level when M   19. The system according to claim 11, wherein the battery connected to the battery power source. A charging circuit, the charging circuit adapted to provide a recharging current to the battery power source The system as described above.   20. 20. The system of claim 19, wherein the charging circuit is the host battery. The system is located in a child device.   21. 20. The system of claim 19, wherein the charging circuit is the modular -The system as located within an electronics component.   22. 20. The system of claim 19, wherein the charging circuit is the battery pack. The system is located in a box.   23. Suitable for modular electronics components for use with host electronics A system for supplying the following power:   With the battery power source disposed inside the modular electronic device component, -Adapted to provide primary power for operating electronic components, said Sufficient to supply a limited quantity of high current demands for modular electronics components A battery power source having a variable capacity; and   Allows the modular electronics components to expand the number of high current demand operations Adapted from the recharge current supplied by the host electronics to the battery power supply The system wherein recharging can be performed on the battery power supply.   24. The system of claim 23, wherein the modular electronics configuration The part is a PCMCIA type module, and the charging circuit is from the host electronic device. Adapted to operate from a 12 volt power supply supplied to PCMCIA model modules The system as described above.   25. In the system according to claim 24:   Host electronics when the charging circuit cannot use a 12 volt power supply Suitable for operation from a 5 volt power supply supplied to the PCMCIA module from Combined; and   The battery power source includes two batteries, which are the modular electronics components. When the power demand of the product is low, it is charged in parallel and the modular electronic device configuration The system, wherein the system is loaded in a serial configuration when the power demand of the component is high.   26. Suitable for modular electronics components for use with host electronics A system for supplying the following power:   Arranged within the modular electronics component, the modular electronics configuration A battery power supply adapted to provide primary power for operating the components; and   A control circuit adapted to detect recharge current to the battery power source, the control A circuit determines the amount of recharge current for the battery power source to the modular electronic equipment configuration. It corresponds to the power consumed by the component and is based on the available recharge rating of the recharge current. The control circuit being configured to transmit in accordance with the above.   27. The system of claim 26, wherein the modular electronics configuration. The part is a PCMCIA type module including a burst mode radio transmitter, Writing system.   28. Suitable for modular electronics components for use with host electronics A system for supplying secondary power, comprising: A modular power supply including a battery power source adapted to provide primary power for operation; The system wherein the electronic component is a PCMCIA type module.   29. 29. The system of claim 28, wherein the PCMCIA model module is Battery pack that includes the battery power supply that is removably attached to the Mu, the system.   30. The system of claim 29, wherein the modular electronics configuration The system wherein the component comprises a wireless transmitter.   31. A system according to claim 30, wherein:   High power consumption level when the transmitter uses the battery power as a power supply In order to maintain a low power consumption level when the battery power supply is not used, Built; and   In connection with the modular electronic components, the transmitter is connected to the high power consumption level. And a device for switching between the low power consumption level and the low power consumption level. .   32. The system according to claim 31, wherein the transmitter is set to a power consumption level. When the device for switching can supply the required power to the battery power supply Automatically switches to the high power consumption level and the battery power source If the bell cannot supply the required power, it will automatically switch to the low power consumption level. The system including a device for replacement.   33. In the system according to claim 31,   The switching device attaches the battery pack to the modular electronic component. Adapted to detect whether it is worn; and   The switching device is also the battery pack and the modular electronic device components. To operate the transmitter at the high power consumption level when attached to Switch, the battery pack is not attached to the modular electronic component. The system being adapted to switch to the low power consumption level when M   34. 31. The system according to claim 30, wherein the battery connected to the battery power source. A charging circuit, the charging circuit adapted to provide a recharging current to the battery power source The system as described above.   35. 35. The system of claim 34, wherein the charging circuit is the host battery. The system is located in a child device.   36. 35. The system of claim 34, wherein the charging circuit is the modular -The system as located within an electronics component.   37. 35. The system of claim 34, wherein the charging circuit is the battery pack. The system is located in a box.   38. The system according to claim 30, wherein the battery pack is rotatably mounted. And the electrically connected antenna to the transmitter of the wireless transmitter. And a device for continuing.